US6882595B2 - Pressure compensated hydrophone - Google Patents

Abstract

A pressure compensated hydrophone for measuring dynamic pressures is disclosed. The hydrophone includes a compliant hollow mandrel with a single optical fiber coiled around at least a portion of the mandrel. The mandrel further includes at least one pressure relief valve for compensating for changes in hydrostatic pressure. The pressure relief valve includes a micro-hole, which allows hydrostatic pressures or low frequency pressure events to couple into the interior of the mandrel to provide compensation against such pressure. Higher frequencies pressure events of interest do not couple through the micro-hole and therefore only act only on the exterior of the mandrel, allowing for their detection. Because (quasi) hydrostatic events are compensated for, the mandrel may be made particularly compliant, rendering the singular fiber optic coil particularly sensitive to the detection of the higher frequency signals of interest.

Description

FIELD OF THE INVENTION

This invention relates generally to hydrophones, and more particularly to a pressure compensated fiber optic hydrophone.

BACKGROUND OF THE INVENTION

Fiber optic hydrophones are well known in the art for measuring seismic and acoustic disturbances. Generally hydrophones are towed behind a ship to measure these disturbances. However, with the increasing development of subsea or land-based oil/well systems, a hydrophone that could be deployed down a well at extreme depths and that could withstand the extremely corrosive downhole environment would provide significant benefits. Such a hydrophone would improve the ability to explore the land surrounding a well site by seismology or to detect other acoustics downhole that could inform the well operator about various aspect of the well's production.

While hydrostatic pressure has a measurable effect on a hydrophone, especially when the hydrophone is deployed at extreme depths, small dynamic pressures, such as propagating acoustic sound waves, have a relatively small effect and therefore are more difficult to measure. When a measurement is to be made at depths where the hydrostatic pressure is great (e.g., thousands of feet down the well), the hydrostatic pressure can overwhelm the acoustic waves by many orders of magnitude.

In an attempt to resolve relatively small dynamic pressures, fiber optic hydrophones generally have two fiber optic “arms”—a sensing arm and a reference arm. Both the sensing arm and the reference arm generally constitute optical fibers coiled around corresponding cylindrical mandrels—an outer compliant mandrel for the sensing arm and an inner rigid mandrel for the reference arm. The compliant mandrel is typically thin walled so that its radius changes easily in response to the acoustic pressures being measured. A cavity is formed between the two mandrels. A gas (e.g., air) or liquid typically fills this cavity. The rigid mandrel may be relatively thick walled, or alternatively thin walled and exposed to the ambient pressure so that its radius would not change. One such hydrophone is disclosed in U.S. Pat. No. 5,394,377 entitled, “Polarization Insensitive Hydrophone,” and is incorporated herein by reference in its entirety. While compliant mandrels are very sensitive, they are subject to damage and collapse when subjected to extremely high hydrostatic pressures, particularly if they are gas-backed. The production of such gas-backed designs is also costly, largely due to the need to seal the air cavity existing between the sensing and reference mandrels. Furthermore, the reference fiber must enter and exit this air cavity without disrupting the seal. Leaking and fiber breakage at this seal commonly can occur during the assembly process.

An alternative design that attempts to alleviate the problems with gas-backed designs comprises a solid core wrapped with a reference coil of optical fiber. A compliant material is formed around the reference coil such that a cavity is eliminated. Then a sensing coil of optical fiber is wound around the compliant material. Such a design is disclosed in U.S. Pat. No. 5,625,724 entitled, “Fiber Optic Hydrophone Having Rigid Mandrel,” which is incorporated herein by reference in its entirety. While this solid design withstands high pressures when deployed at extreme depths, the design lacks in sensitivity to detect acoustic pressure waves and requires two windings of optical fibers. Other fiber optic hydrophone designs can be found in U.S. Pat. Nos. 5,625,724; 5,317,544; 5,668,779; 5,363,342; 5,394,377, which are also incorporated herein by reference.

The art would benefit from a hydrophone sensitive enough to measure relatively small dynamic pressures while being able to withstand deployment in environments having large hydrostatic pressures. It would be further beneficial for such a hydrophone to contain a single measurement coil, without the need for a reference coil.

SUMMARY OF THE INVENTION

A pressure compensated hydrophone for measuring dynamic pressures is disclosed. The hydrophone includes a compliant hollow mandrel with a single optical fiber coiled around at least a portion of the mandrel. The mandrel further includes at least one pressure relief valve for compensating for changes in hydrostatic pressure. The pressure relief valve includes a micro-hole that allows hydrostatic pressures or low frequency pressure events to couple into the interior of the mandrel to provide compensation against such pressure. Higher frequency pressure events of interest do not couple through the micro-hole and therefore act only on the exterior of the mandrel, allowing for their detection. Because (quasi) hydrostatic events are compensated for, the mandrel may be made particularly compliant, rendering the singular fiber optic coil particularly sensitive to the detection of the higher frequency signals of interest.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other features and aspects of the present disclosure will be best understood with reference to the following detailed description of embodiments of the invention, when read in conjunction with the accompanying drawings, wherein:

FIG. 1 illustrates a cross sectional view of one embodiment of a pressure compensated hydrophone incorporating a single pressure relief valve.

FIG. 2 illustrates a cross sectional view of one embodiment of a pressure compensated hydrophone incorporating first and second pressure relief valves.

FIG. 3 illustrates a perspective view of an embodiment of a pressure compensated hydrophone.

FIG. 4 illustrates a perspective view of another embodiment of a pressure compensated hydrophone.

FIG. 5 illustrates a cross sectional view of one embodiment of a pressure compensated hydrophone package assembly.

FIG. 6 schematically illustrates an array of hydrophone package assemblies deployed in a well and connected by inter-station cables.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

In the interest of clarity, not all features of actual implementations of a pressure compensated hydrophone are described in the disclosure that follows. It will of course be appreciated that in the development of any such actual implementation, as in any such project, numerous engineering and design decisions must be made to achieve the developers' specific goals, e.g., compliance with mechanical and business related constraints, which will vary from one implementation to another. While attention must necessarily be paid to proper engineering and design practices for the environment in question, it should be appreciated that the development of a pressure compensated hydrophone would nevertheless be a routine undertaking for those of skill in the art given the details provided by this disclosure.

FIG. 1 depicts an embodiment of a pressure compensatedhydrophone10. Thehydrophone10 includes a preferably flattened oblique mandrel24 (shown best inFIG. 4) that contains a pressure-relief valve12 and aninner cavity32. Theinner cavity32 spans a portion of the length of themandrel24 and is preferably filled with a high-viscosity low bulk modulus fluid, such as silicone oil, such that substantially no air is present within theinner cavity32. Theinner cavity32 acts in tandem with thepressure relief valve12 to provide pressure compensation for thehydrophone10, as described in more detail below. Theinner cavity32 is bounded by awall25 to define asensing region33 of thehydrophone10. The hydrophone can range from 0.4 to 12 inches in length and from 0.4 to 1.5 inches in diameter, depending on the application at hand.

Themandrel24 is preferably made of a homogenous material, which will impart a compliance towall25 suitable for the particular application at hand. Metal alloys providing suitable compliancy and chemical robustness for oil/gas well applications include non-ferrous alloy materials, alloy steel, or stainless steel. The compliance may vary depending on factors such as the thickness of themandrel wall25, and the physical properties of the mandrel material, e.g. its modulus of elasticity. These factors and others may be chosen to help produce favorable sensor sensitivity for detecting the frequencies and magnitudes of interest, as one skilled in the art will realize. For an oil/gas well application, it is preferred that thewall25 be from 0.005 to 0.1 inches thick, and that thesensing region33 be from 0.1 to 10 inches long. Different materials or pieces could be used for themandrel24 and thewall25, although it is preferred that they be integral. Themandrel24 may be formed by standard metal working processes, pressing methods, or an extrusion or drawing process.

A standardoptical fiber26 is coiled around the outside of themandrel24 under a predetermined amount of tension and along at least a portion of thesensing region33. Thiscoil55 is preferably secured in place around thesensing region33 by covering it with, an epoxy, adhesive, encapsulating or potting compound, or any other securing means (not shown) capable of withstanding environment (e.g., temperature) into which the mandrel will be deployed. When thehydrophone10 is subjected to a pressure, e.g., P_O, that pressure will exert a force perpendicular to the sensing region as shown. Thus, in thesensing region33, the pressure will compress themandrel24 inward causing thewall25 of themandrel24 to deform. When themandrel24 deforms, thecoil55 ofoptical fiber26 will correspondingly change in length. Optical detection of this change in length thus allows a determination of the pressure, Po, as will be described in more detail below.

The sensitivity of a fiber optic hydrophone using interferometry principles is a function of the change of strain of thefiber optic coil55. As noted previously, thecoil55 is preferably pre-strained, or tension wound, such that when thewall25 of themandrel24 deforms inward, thecoil55 will still maintain intimate contact with thewall25. Maintaining such contact thus helps to maximize the sensitivity of the coil and increases the magnitude of pressures that may be detected. The other objective of pretension is to keep the sensing fiber always in tension and not operating in the compressional mode. Coil sensitivity is further affected by the number of turns in thecoil55. As the mandrel deforms, each turn of thecoil55 will change in length by a slight amount, but this amount is amplified, and therefore easier to optically resolve, when more turns are used. In short, increasing the number of turns will generally increase the sensitivity of thecoil55. While an appropriate length will necessarily depend on the application in question, coil lengths of 5 to 300 feet are believed preferable for detection of downhole acoustics. Thecoil55 can consist of a single layer or multiple stacked layer ofoptical fiber26 depending on the application.

Themandrel24 may further includepre-drilled holes49,53 to aid in its attachment to another body as described in more detail below. As shown inFIG. 1 themandrel24 is formed around a discretely formedpressure relief valve12, although the mandrel and the housing of the valve may be formed as one integrated unit.

Preferably, thefiber26 further includes fiber Bragg gratings (FBGs)27a,27badjacent to both ends of thecoil55. Light reflected from theFBGs27a,27bprovides information about the length of the optical fiber, and hence the pressure of the detected acoustics, between the two FBGs. If the FBGs have the same reflection wavelength, the reflected signals will form an interference pattern that can be resolved using fringe counting techniques or other demodulation techniques. One method for interrogating a coil using an interferometric approach is disclosed in U.S. patent application Ser. No. 09/726,059, entitled “Method and Apparatus for Interrogating Fiber optic Sensors,” filed Nov. 29, 2000, which is incorporated herein by reference in its entirety.

It should be noted that the use of FBGs bounding thecoil55 is not strictly necessary. If thehydrophone10 does not contain FBGs, other known interferometric techniques may be used to determine the change in length (circumferential or axial) of thecoil55, such as by Mach Zehnder or Michaelson interferometric techniques, which are disclosed in U.S. Pat. No. 5,218,197, entitled “Method and Apparatus for the Non-invasive Measurement of Pressure Inside Pipes Using a Fiber Optic Interferometer Sensor,” issued to Carroll, and which is incorporated herein by reference in its entirety. The coils may be multiplexed in a manner similar to that described in Dandridge et al., “Fiber Optic Sensors for Navy Applications,” IEEE, February 1991, or Dandridge et al., “Multiplexed Interferometric Fiber Sensor Arrays,” SPIE, Vol. 1586, 1991, pp. 176-183, which are also incorporated herein by reference in their entireties.

Alternatively, the FBGs may have different reflection wavelengths in a Wavelength Division Multiplexing (WDM) approach. Moreover, the FBGs themselves, instead of thecoil55 between them, can be coiled around the sensor and used as the sensor(s) for the hydrophone. In such an embodiment, the deformation of thewall25 would manifest as shifts in the reflection wavelengths of the FBGS, which could be correlated to the pressures being detected, as is well known and not further discussed. In the preferred embodiment ofFIG. 1, theFBGs27a,27bare located so as to experience little to no strain, as strain on the FBGs will shift the wavelength of light reflected therefrom which might disturb the pressure measurement. Thus, the optical fiber preferably lies along themandrel24 at least slightly outside of thesensing region33 andcompliant wall25. Alternatively, theFBGs27a,27bmay be isolated from thewall25 by isolation pads or similar devices, as is disclosed in U.S. patent application Ser. No. 09/726,060 entitled “Apparatus For Protecting Sensing Devices,” filed Nov. 29, 2000, now U.S. Pat. No. 6,501,067, which is incorporated herein by reference in its entirety.

As alluded to earlier, the disclosed hydrophone further includes apressure relief valve12 to compensate for changes in hydrostatic pressure, which may result as the hydrophone is deployed deeper and deeper into a well. Thepressure relief valve12 preferably includes a micro-hole14. This micro-hole14 acts as a mechanical low pass filter that has a diameter such that pressure waves above a certain frequency, e.g., 3 Hz, are unable to pass through the micro-hole14. Because these higher frequencies will not exert a pressure on thevalve12, they will not affect the pressure inside theinner cavity32, which allows the presence of such higher frequency components to be detected by thecoil55. By contrast, frequencies below this cut off will exert pressure both inside and outside of the coil, and will not be detectable. As most frequencies of interest in acoustic phenomenon to be detected are above this range, this frequency limitation does not appreciably limit the operation of the hydrophone. In a preferred embodiment, the diameter of micro-hole14 ranges from about 0.001 to 0.1 inches.

The micro-hole14 in conjunction with thevalve12 allows for the compensation of hydrostatic pressures. Thevalve12 includes ahousing23 containing aball18 normally biased against an elastomeric O-ring22 by aspring16. Thespring16 exerts a predetermined force against the ball18 (“valve closing force”), which is determined by the amount of compression of the spring and its spring constant. Preferably, this force maintains approximately a 50 psi difference between the P_Iof theinner cavity32 and the P_Oof the outer environment. In one embodiment, thevalve12 may comprise a 0.187″ Unscreened Pressure Relief Valve manufactured by The Lee Company. This valve is constructed entirely of stainless steel, has a diameter of {fraction (3/16)} inch, is approximately ½ inch long, and imparts a valve closing force from 20 to 100 psi.

As the components of thevalve12 may become exposed to the fluids present in the well, it is preferred that they be made of suitably resilient materials.Ball18 may be made of a metal alloy such as stainless steel, ceramic, or plastic or rubber materials such as closed cell synthetic rubber, solid natural rubber, polyurethane, polyethylene, silicone rubber, or neoprene. Theball18 may be hollow and may take other shapes (e.g., cylindrical) so long as it is movable in response to the increasing external pressure and is capable of forming a good seal. If the ball is made of a deformable material, the O-ring22 may be eliminated from thepressure relief valve12. Thespring16 preferably comprises a metal alloy such as stainless steel. Biasing means other than springs may also be used so long as they are sufficient to maintain the required internal pressure P_Iwithin the inner cavity.

It is preferred to form thevalve12 within itshousing23 before coupling thehousing23 to themandrel24, although these components can be formed as an integral piece. Coupling between thehousing23 and themandrel24 may be effectuated by a screw relationship, by welding, or by other well known means (not shown). Thereafter, theinner cavity32 of the hydrophone can be filled with oil by using a thin probe to depress the ball and introducing oil through the micro-hole14. Alternatively, theinner cavity32 can be filled with oil prior to the coupling of thehousing23 to themandrel24.

As noted earlier, some prior art hydrophones were limited with respect to the pressures to which they could be exposed, as high pressures presented the risk of collapsing the relatively thin wall around which the sensing coils were wrapped. This problem has been alleviated in the disclosed hydrophone design because the pressure inside of the hydrophone can roughly be brought into equilibrium with the external hydrostatic pressure. When the external pressure P_Oexceeds the valve closing force of valve12 (e.g., 50 psi), theball18 of thevalve12 will start to open, which allows the external pressure to couple into the inner cavity throughmicro-hole14. (Depending on the viscosity of the oil in theinner cavity32 and the diameter of theball18 within itshousing23, the well fluid and the oil within the hydrophone may mix, but this is not deleterious to the operation of the hydrophone. Should particulates in the well fluid cause concern that the valve might become jammed, a mesh or screen (not shown) may be placed within the micro-hole14). Accordingly, thehydrophone10 may be deployed to great depths and subjected to great pressures (e.g., 20,000 psi) while still retaining a relatively thin (and dynamically sensitive)wall25, which is capable of detecting higher frequency acoustic phenomenon as explained earlier.

FIG. 2 discloses an embodiment of the hydrophone which provides both descending and ascending pressure compensation, and which incorporates twopressure relief valves12a,12b.Valve12aallows for descending pressure compensation, as described above.Valve12b,which is similar (or identical) in structure tovalve12a,allows for ascending pressure compensation, and operates as follows. When thehydrophone10 is raised from a lower depth to a higher depth, the external hydrostatic pressure decreases. Because the inner cavity had been coupled to a higher pressure at the lower depth, the volume of the fluid within theinner cavity32 will expand at the higher depth. When the pressure of theinner cavity32 exceeds the sum of the external pressure and the valve closing force ofvalve12b(again, preferably 50 psi),valve12bwill open and equilibrate the external and internal pressures. When the external pressures fall below the valve closing force (e.g., 50 psi),valve12bwill close, thus trapping the fluid within theinner cavity32 at the valve closing force. One skilled in the art will recognize thatvalves12aand12bare “one way” valves. Accordingly, when the hydrophone descends,valve12bis prevented from opening due to the pressure theball18bexerts on the O-ring22b;similarly, when the hydrophone ascends,valve12ais prevented from opening due to the pressure theball18aexerts on the O-ring22a.In summary, the structural integrity of thehydrophone10 as shown inFIG. 2 remains intact as the hydrostatic pressure changes.

Depending on the application at hand, an embodiment of the disclosed hydrophone could have either or both of thevalves12a,12b.For example, if it is not anticipated that thehydrophone10 will be retrieved,valve12b,providing for ascending pressure relief, may not be necessary. Moreover, if thehydrophone10 is not going to be placed sufficiently deeply such that descending pressure compensation will cause a problem, or if the inner cavity can be pre-pressurized to a suitably high value, thenvalve12a,providing for descending pressure relief, may not be necessary. Additionally, in an embodiment having bothvalves12a,12b,the valve closing forces of the two valves need not be the same.

The disclosedhydrophone10 may be cylindrical in shape as shown perspectively inFIG. 3, but may also comprise a preferable more flattened shape as shown in FIG.4. This flattened, oblique cylindrical, shape renders the hydrophone more sensitive to the dynamic acoustic pressures being measured, as the hydrophone is more compliant along the elongated surfaces when compared with a cylindrical embodiment.

FIG. 5 discloses thehydrophone10 within aperforated housing34 to form ahydrophone package assembly20. Essentially,housing34 provides mechanical protection to the hydrophone10 (and particularly to the fiber optics), while still allowing dynamic and static pressures to couple to thehydrophone10 throughholes75. Thehousing34 may include a first recessedend76 and a secondopen end77. The first recessedend76 of thehousing34 is joined to adisc35. Thedisc35 and thehousing34 are composed of a metal suitable for the intended environment of thehydrophone assembly20, such as stainless steel or inconel. Thedisc35, thehousing34, or both further include pressure relief holes75 for allowing the well bore fluid to enter into thehousing cavity42. Preferably thefiber26 is sufficiently encapsulated with a coating material, such as an epoxy, to protect thefiber26 from the corrosive effects of the well bore fluid. The thickness of thedisc35 orhousing34 may be varied depending on the temperature and harshness of the environment and the expected pressure. Thedisc35 is preferably joined to the recessedend76 of thehousing34 by laser welding, although other techniques or methods known in the art can be used. Furthermore, thedisc35 and thehousing34 may be formed into one integral housing or sleeve as opposed to joining two separate pieces together. Thesecond end77 of thehousing34 is joined to anend cap46, which further includes anoptical feedthrough38 such as disclosed in U.S. patent application Ser. No. 09/628,264, entitled “Optical Fiber Bulkhead Feedthrough Assembly And Method For Making Same,” filed on Jul. 28, 2000, now U.S. Pat. No. 6,526,212, which is incorporated herein by reference. Thefiber optic feedthrough38 allows thefiber26 to pass through theend cap46 on its way to the optical source/detection equipment preferably residing at the surface of the well (not shown). Ametal capillary tube44, or series of interconnecting tubes, preferably protects thefiber26 as it exits thehousing34. The capillary tube(s)44 is preferably welded to theend cap46, and details concerning the welding process and other applicable manufacturing details are disclosed in U.S. patent application Ser. No. 10/266,903, entitled “Multiple Component Sensor Mechanism,” filed Oct. 6, 2002, which is incorporated herein by reference. Thefeedthrough38 preferably seals thefiber26 in place with an epoxy, glass, or other sealing material known in the art depending on the intended pressure and temperature to be encountered. Theend cap46 may then be threadably connected to thehousing34 or may be connected by other known mechanical means or by welding. If theend cap46 is welded to thehousing34, the end cap should have anend cap shoulder57 that extends a sufficient distance within the inner dimension of thehousing34 to dissipate heat during the welding operation. For example, theshoulder57 of theend cap46 may extend approximately 4.5 mm into thehousing34, which has an inner dimension of approximately 19 mm.

Thehydrophone10 is supported within thehousing34 preferably by the use of locatingpins48 attached to theend cap46, which may be similar to clevis pins. The locating pins48 fit withinpre-drilled holes49 where a secondsmaller pin52, such as or similar to a cotter pin, is inserted into the locatingpin48 to lock the locatingpin48 in place. Thehydrophone10 may further include a secondpre-drilled hole53 for the placement of the smaller pin52 (see FIG.2). Thehydrophone10 is thus sufficiently supported within thehousing34 without making contact thereto except at the location of the pin mechanisms. As one will realize, one or more pin/locating pin mechanisms may be employed, and the scope of the present invention is not limited to the embodiments shown. Additionally, thehydrophone10 may be affixed within thehousing34 in other ways, as one skilled in the art will realize.

Alternatively, thehousing cavity42 may be sealed from the well bore fluid. With asolid housing34 and a corrugated diaphragm (not shown), instead of aperforated disc35, the hydrophone10 (and in particular the fiber optics) would be protected from the corrosive affects of the well bore fluid. In such an embodiment, thehousing cavity42 may be filled with a fluid such as silicone fluid. To alleviate the thermal expansion of the fluid when thehydrophone assembly20 is exposed to high temperatures, a compensator (not shown) is preferably disposed within thehousing34. The compensator has a variable volume responsive to the thermal expansion of the fluid. The compensator may preferably comprise a hollow bellow composed of metal. In an additional embodiment, thehydrophone10 may preferably be enclosed within compliant tubing, which provides for static pressure compensation as well as allows the dynamic acoustics to couple into the tubing. Such compliant tubing may be formed from polyurethane or other similar plastic material. Furthermore, the tubing may be fluid-filled or alternatively have a solid core filled with, for example, polyurethane foam or other suitable material.

Thehydrophone assembly20 allows for thecoil55 to sense dynamic acoustic pressure waves. Thehydrophone assembly20 is designed to be deployed in the well annulus between the production pipe54 (shown inFIG. 6) and the well casing62 where it will be subjected to high temperatures, pressures, and potentially caustic chemicals or mechanical damage by debris within the annulus. Because these conditions could potentially damage an optical fiber, the pressure relief holes75 may further include a mesh or filter device for preventing the entry of particles into the housing cavity while allowing the entry of static and dynamic pressures. The dynamic acoustics then exert a pressure onto thehydrophone10 deforming thecoil55. The dynamic acoustics may then be detected, while the hydrostatic pressures are compensated for within thehydrophone cavity32 as described previously. It should be noted however that the use of ahousing34 is not strictly necessary, and the hydrophone could work in a given environment without such a housing. If ahousing34 is not used, the fiber optic cable andcoil55 should be coated for protection, for example, with a suitably resilient epoxy as mentioned earlier.

Turning to the schematic illustration inFIG. 6, a fiber optic in-wellseismic array68 used in the exploration of a hydrocarbon reservoir is depicted. Thearray68 has a plurality ofseismic stations60 which include the disclosedhydrophone package assemblies20 interconnected byinter-station cables56. Thearray68 is shown deployed in a well50, which has been drilled down to a subsurface production zone and is equipped for the production of petroleum effluents. Typically, the well50 includes acasing62 coupled to the surrounding formations by injected cement.Production tubing54 is lowered into the cased well50 with the seismic stations clamped thereto, which may be accomplished using the techniques and apparatuses disclosed in U.S. patent application Ser. No. 10/266,715, entitled “Apparatus and Method for Transporting, Deploying, and Retrieving Arrays Having Nodes Interconnected by Sections of Cable,” filed Oct. 6, 2002, which is incorporated by reference in its entirety. The well50 can be fifteen to twenty thousand feet or more in depth.

Theseismic stations60 includehydrophone assemblies20 andclamp mechanisms64 such as disclosed in U.S. Provisional Patent Application Serial No. 60/416,932, entitled “Clamp Mechanism for In-Well Seismic Sensor,” filed Oct. 6, 2002, now U.S. patent application Ser. No. 10/678,963 filed on Oct. 3, 2003, which is incorporated by reference in its entirety. Thehydrophone assemblies20 are interconnected by theinter-station cables56 to aninstrumentation unit70, which may be located at the surface or on an oil platform (not shown). Theinstrumentation unit70 typically includes optical source/detection equipment, such as a demodulator and/or optical signal processing equipment (not shown). The inter-station cables56 (i.e.,cable44 ofFIG. 5) are typically ¼ inch diameter cables housing optical fibers between thehydrophone assemblies20 and theinstrumentation unit70.

The optical source within theinstrumentation unit70 may include a semiconductor laser diode that may be pulsed to effectuate the preferred interferometric coil interrogation technique discussed earlier. However, and as one skilled in the art understands, there are various other optical signal analysis approaches that may be used to analyze the reflected signals from the hydrophone, such as (1) direct spectroscopy, (2) passive optical filtering, (3) tracking using a tunable filter, or (4) fiber laser tuning (if a portion or all of the fiber between a pair of FBGs is doped with a rare earth dopant). Examples of a tunable laser can be found in U.S. Pat. Nos. 5,317,576; 5,513,913; and 5,564,832, which are incorporated herein by reference. One skilled in the art will also appreciate that the use of a fiber optic sensor in the disclosed hydrophone easily lends itself to multiplexing to other hydrophones or to other fiber optic devices along a single fiber optic transmission cable (i.e., cables56), such as by the TDM or WDM approaches alluded to earlier.

The disclosedhydrophone assembly20 has many potential downhole uses, but is believed to be particularly useful in vertical seismic profiling to determine the location of petroleum effluents in the geologic strata surrounding the well in which the hydrophones are deployed. (Further details concerning vertical seismic profiling are disclosed in U.S. patent application Ser. No. 09/612,775, entitled “Method and Apparatus for Seismically Surveying an Earth Formation in Relation to a Borehole,” filed Jul. 10, 2000, now U.S. Pat. No. 6,601,671, which is incorporated herein by reference in its entirety). As is known, a seismic generator (not shown) detonated at the surface near the well is used to generate acoustic waves which reflect off of the various strata and are detected by thehydrophone assemblies20 at eachseismic station56. In this application, theseismic stations60 are distributed over a known length, for example, 5000 feet. Over the known length, theseismic stations60 can be evenly spaced at desired intervals, such as every 10 to 50 feet, as is necessary to provide a desired resolution. Accordingly, the fiber optic in-wellseismic array68 can include hundreds ofhydrophone assemblies20 and associatedclamp mechanisms64. Because fiber optic connectors on theinter-station cables56 between thehydrophone assemblies20 can generate signal loss and back reflection of the interrogating signals, the use of such connectors is preferably minimized or eliminated in the array. Instead, it is preferred to splice together the various components along a single fiber optic cable, which minimizes signal loss. Such splicing may be performed in accordance with the techniques disclosed in U.S. patent application Ser. No. 10/266,903, which has already been incorporated herein. If optical loss is still too significant along the entirety of the array even when splicing is used, different fiber optic cables can be used to interrogate different sections of the array, which requiresinter-station cable56 to possibly carry multiple fiber optic cables.

As used herein, “hydrostatic pressure” should be understood to include low frequency “quasi static” pressures capable of coupling into the inner cavity of the hydrophone, and hence which are not detectable as explained earlier. Moreover, a “valve” should be understood as meaning a discrete component for selectively blocking or not blocking the transfer of fluid. Accordingly, a “valve” should not be understood as referring to a mere port, conduit, or hole, even if such a port, conduit, or hole acts to restrict the transfer of fluid in certain circumstances.

The invention is not limited to the abovedisclosed embodiments, but instead is defined by the following claims and their equivalents.

Claims (70)

1. A hydrophone assembly deployable in an external environment having a first hydrostatic pressure, the hydrophone for measuring dynamic acoustic pressures present in the external environment, comprising:

a mandrel with an inner cavity, wherein the inner cavity is at a second pressure and defines a sensing region of the mandrel;

an optical fiber secured to at least a portion of an exterior of the sensing region; and

at least one pressure relief valve positioned between the first pressure and the second pressure for selectively coupling the second pressure to the first pressure.

2. The hydrophone assembly ofclaim 1, wherein the sensing region is compliant in response to the dynamic acoustic pressures.

3. The hydrophone assembly ofclaim 1, wherein the inner cavity is liquid filled.

4. The hydrophone assembly ofclaim 3, wherein the liquid comprises silicone oil.

5. The hydrophone assembly ofclaim 1, wherein the optical fiber is coiled around the sensing region.

6. The hydrophone assembly ofclaim 5, wherein the optical fiber coil is bounded by first and second fiber Bragg gratings.

7. The hydrophone assembly ofclaim 6, wherein the first and second gratings have equal reflection wavelengths.

8. The hydrophone assembly ofclaim 1, wherein the optical fiber secured to the sensing region comprises at least one fiber Bragg grating.

9. The hydrophone assembly ofclaim 1, wherein the valve is enclosed within a valve housing coupled to the mandrel.

10. The hydrophone assembly ofclaim 1, wherein the valve couples the pressures when the first pressure exceeds the second pressure by a valve closing force of the valve.

11. The hydrophone assembly ofclaim 1, wherein the valve couples the pressures when the second pressure exceeds the first pressure by a valve closing force of the valve.

12. The hydrophone assembly ofclaim 1, wherein the hydrophone comprises a first valve and a second valve, and wherein the first valve couples the pressures when the first pressure exceeds the second pressure by a first predetermined amount, and wherein the second valve couples the pressures when the second pressure exceeds the first pressure by a second predetermined amount.

13. The hydrophone assembly ofclaim 12, wherein the first predetermined amount comprises a first valve closing force for the first valve, and the second predetermined amount comprises a second valve closing force for the second valve.

14. The hydrophone assembly ofclaim 13, wherein the first and second valve closing forces are equal.

15. The hydrophone assembly ofclaim 1, wherein the valve comprises a spring.

16. The hydrophone assembly ofclaim 1, wherein the mandrel comprises a cylinder.

17. The hydrophone assembly ofclaim 1, wherein the mandrel comprises an oblique cylinder.

18. The hydrophone assembly ofclaim 1, further comprising a housing, wherein the mandrel is contained within the housing, wherein the first pressure is present within a space between the mandrel and the housing, and wherein the first pressure couples into the space through the housing.

19. The hydrophone assembly ofclaim 18, wherein the first pressure couples into the space through at least one hole within the housing.

20. The hydrophone ofclaim 18, wherein the space is liquid filled.

21. A hydrophone assembly deployable in an external environment having a first hydrostatic pressure, the hydrophone for measuring dynamic acoustic pressures present in the external environment, comprising:

a mandrel with an inner cavity, wherein the inner cavity is at a second pressure and defines a sensing region of the mandrel;

an optical fiber secured to at least a portion of an exterior of the sensing region; and

at least one pressure relief valve having a valve closing force positioned between the first pressure and the second pressure, wherein the valve couples the second pressure to the first pressure when the differential pressure between the first and second pressures exceeds the valve closing force.

22. The hydrophone assembly ofclaim 21, wherein the sensing region is compliant in response to the dynamic acoustic pressures.

23. The hydrophone assembly ofclaim 21 wherein the inner cavity is liquid filled.

24. The hydrophone assembly ofclaim 23, wherein the liquid comprises silicone oil.

25. The hydrophone assembly ofclaim 21, wherein the optical fiber is coiled around the sensing region.

26. The hydrophone assembly ofclaim 25, wherein the optical fiber coil is bounded by first and second fiber Bragg gratings.

27. The hydrophone assembly ofclaim 26, wherein the first and second gratings have equal reflection wavelengths.

28. The hydrophone assembly ofclaim 21, wherein the optical fiber secured to the sensing region comprises at least one fiber Bragg grating.

29. The hydrophone assembly ofclaim 21, wherein the valve is enclosed within a valve housing coupled to the mandrel.

30. The hydrophone assembly ofclaim 21, wherein the valve couples the pressures when the first pressure exceeds the second pressure by the valve closing force.

31. The hydrophone assembly ofclaim 21, wherein the valve couples the pressures when the second pressure exceeds the first pressure by the valve closing force.

32. The hydrophone assembly ofclaim 21, wherein the hydrophone comprises a first valve having a first valve closing force and a second valve having a second valve closing force, and wherein the first valve couples the pressures when the first pressure exceeds the second pressure by the first valve closing force, and wherein the second valve couples the pressures when the second pressure exceeds the first pressure by the second valve closing force.

33. The hydrophone assembly ofclaim 32, wherein the first and second valve closing forces are equal.

34. The hydrophone assembly ofclaim 21, wherein the valve comprises a spring for providing the valve closing force.

35. The hydrophone assembly ofclaim 21, wherein the mandrel comprises a cylinder.

36. The hydrophone assembly ofclaim 21, wherein the mandrel comprises an oblique cylinder.

37. The hydrophone assembly ofclaim 21, further comprising a housing, wherein the mandrel is contained within the housing, wherein the first pressure is present within a space between the mandrel and the housing, and wherein the first pressure couples into the space through the housing.

38. The hydrophone assembly ofclaim 37, wherein the first pressure couples into the space through at least one hole within the housing.

39. The hydrophone ofclaim 38, wherein the space is liquid filled.

40. A hydrophone assembly deployable in an external environment having a first hydrostatic pressure, the hydrophone for measuring dynamic acoustic pressures present in the external environment, comprising:

a mandrel with an inner cavity, wherein the inner cavity is at a second pressure and defines a sensing region of the mandrel;

an optical fiber secured to at least a portion of an exterior of the sensing region; and

means for selectively coupling the second pressure to the first pressure when the differential pressure between the first and second pressures exceeds a predetermined amount.

41. The hydrophone assembly ofclaim 40, wherein the sensing region is compliant in response to the dynamic acoustic pressures.

42. The hydrophone assembly ofclaim 40, wherein the inner cavity is liquid filled.

43. The hydrophone assembly ofclaim 42, wherein the liquid comprises silicone oil.

44. The hydrophone assembly ofclaim 40, wherein the optical fiber is coiled around the sensing region.

45. The hydrophone assembly ofclaim 44, wherein the optical fiber coil is bounded by first and second fiber Bragg gratings.

46. The hydrophone assembly ofclaim 45, wherein the first and second gratings have equal reflection wavelengths.

47. The hydrophone assembly ofclaim 40, wherein the optical fiber secured to the sensing region comprises at least one fiber Bragg grating.

48. The hydrophone assembly ofclaim 40, wherein the predetermined amount comprises a valve closing force.

49. The hydrophone assembly ofclaim 40, wherein the mandrel comprises a cylinder.

50. The hydrophone assembly ofclaim 40, wherein the mandrel comprises an oblique cylinder.

51. The hydrophone assembly ofclaim 40, further comprising a housing, wherein the mandrel is contained within the housing, wherein the first pressure is present within a space between the mandrel and the housing, and wherein the first pressure couples into the space through the housing.

52. The hydrophone assembly ofclaim 51, wherein the first pressure couples into the space through at least one hole within the housing.

53. The hydrophone ofclaim 51, wherein the space is liquid filled.

54. A method of using a hydrophone assembly deployable in an external environment having a first hydrostatic pressure to detect dynamic acoustic pressures present in the external environment caused by a seismic disturbance, comprising:

causing a seismic disturbance to create dynamic acoustic pressures; and

detecting the dynamic acoustic pressures with the hydrophone, wherein the hydrophone comprises:

a mandrel with an inner cavity at a second pressure and defining a sensing region of the mandrel;

an optical fiber secured to at least a portion of an exterior of the sensing region; and

at least one pressure relief valve positioned between the first pressure and the second pressure for selectively coupling the second pressure to the first pressure.

55. The method ofclaim 54, further comprising deploying the hydrophone in a well.

56. The method ofclaim 55, wherein the well contains a casing, and further comprising deploying the hydrophone to couple the hydrophone to the casing.

57. The method ofclaim 56, wherein the hydrophone is deployed from production tubing.

58. The method ofclaim 54, wherein detecting the dynamic acoustic pressures includes sensing a compliant response of the sensing region to the dynamic acoustic pressures.

59. The method ofclaim 54, further comprising filling the inner cavity with a liquid.

60. The method ofclaim 54, further comprising filling the inner cavity with a silicone oil.

61. The method ofclaim 54, wherein the optical fiber is coiled around the sensing region.

62. The method ofclaim 54, wherein detecting the dynamic acoustic pressures includes analyzing signals from first and second fiber Bragg gratings in the optical fiber, the optical fiber having a coil around the sensing region bounded by the first and second fiber Bragg gratings.

63. The method ofclaim 54, further comprising enclosing the valve within a valve housing coupled to the mandrel.

64. The method ofclaim 54, wherein the valve couples the pressures when the first pressure exceeds the second pressure by a valve closing force of the valve.

65. The method ofclaim 54, wherein the valve couples the pressures when the second pressure exceeds the first pressure by a valve closing force of the valve.

66. The method ofclaim 54, wherein the hydrophone comprises a first valve and a second valve, and wherein the first valve couples the pressures when the first pressure exceeds the second pressure by a first predetermined amount, and wherein the second valve couples the pressures when the second pressure exceeds the first pressure by a second predetermined amount.

67. The method ofclaim 66, wherein the first predetermined amount comprises a first valve closing force for the first valve, and the second predetermined amount comprises a second valve closing force for the second valve.

68. The method ofclaim 67, further comprising compensating for changes in hydrostatic pressure with the first and second valve closing forces that are equal.

69. The method ofclaim 54, further comprising containing the mandrel within a housing, wherein the first pressure is present within a space between the mandrel and the housing, and wherein the first pressure couples into the space through the housing.

70. The methodclaim 69, further comprising filling the space with liquid.

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